Multi-sectioned arms for portable electronic devices

ABSTRACT

Multi-sectioned arms are used as a basic mechanism for coupling the display and the base of a portable computer. With this mechanism, one single computer can support all of the following capabilities. The display can move continuously, relative to the back edge of the base, along any combination of up and down, backward and forward, and left and right directions. The display can be tilted up and down as well as sideway for viewing angle adjustment, and also set to portrait and landscape orientations. When the display is in conventional open or close positions, each arm can be folded and parked alongside and parallel to as well as away from the edge of the base. The arms can be detached from the computer. The base and the display can overlay each other in four ways. Finally, mechanical mechanisms for implementations of the arms and connections to the computer including friction joint mechanisms and attachment mechanisms for connecting the arm to the display and the base, are presented. A method of assembling the multi-sectioned arm is presented.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of U.S. patent applicationSer. No. 11/999,620, filed on Dec. 6, 2007.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not Applicable

REFERENCE TO SEQUENCE LISTING, A TABLE OR A COMPUTER PROGRAM LISTINGCOMPACT DISC APPENDIX

Not Applicable

FIELD OF THE INVENTION

The present invention generally relates to a computer and otherelectronic devices. More specifically, the invention relates to portablecomputers having an adjustable display.

BACKGROUND

Technological advancements have enabled portable computers to be builtin various forms such as notebooks, tablet PC, personal digitalassistants (PDA), and even video game players, and portable DVD players.In this patent application, we use the following terms “portablecomputer”, “portable electronic device”, and “portable computing device”interchangeably to refer to these various forms, to which the presentinvention is not only applicable individually but useful in unifyingsome of them into one single portable computer with multipleconfigurations.

A portable computer typically comprises a base and a screen. Thecomputer base generally holds the central processing unit (CPU), memory,electronic circuitry and other components, such as a keyboard, a diskdrive. Typically, the base is hinged to the display in a manner in whichthe display folds down on the base, as shown by the computer (900) inFIG. 5. This design is referred to as the clam shell type enclosure. Thedisplay screen is typically connected to the base in such a way that thescreen is hidden when the clam shell is closed. That is, the screenfaces the upper side (typically, the keyboard) of the base.

There are several disadvantages of the clam shell design. Onedisadvantage is that the screen and the keyboard are next to each other.If the screen is placed at a comfortable viewing position, it will makethe arms and shoulders uncomfortable for typing. On the other hand, ifthe computer is placed at a comfortable typing position, it would makethe neck uncomfortable when looking at the screen. This problem cancause serious computer-related work injuries. Another disadvantage isthat it needs to sufficient room to fully open the clam shell computerand position the display screen at an angle of about ninety (90°) ormore with respect to the base for normal viewing; and this can be verydifficult when operating in tight space, such as on the pull-out tray onthe back of a declined airplane seat. Therefore, the clam shell designis insufficient for comfortable use.

In general, it is useful to be able to arrange a single portablecomputer into various configurations as follows.

-   -   (1) Improved Notebook configuration: The display screen can be        adjusted to a desirable viewing angle, and to a position by        height (up or down relative to the base) and by depth (forward        or backward relative to the base's user edge).    -   (2) Shared viewing configuration: This is configuration (1) plus        display adjustment by width (left or right of the space above        the keyboard). In addition, this configuration allows the        display to tilt left and right relative to the usage orientation        of the keyboard. This configuration can be useful when more than        one people are looking at the screen at the same time.    -   (3) Tablet PC configuration: The portable computer is closed        with the base stacked underneath the upward-facing screen to be        used as input pad. (The keyboard in this configuration can        either be facing down or up. But it does not matter.)    -   (4) Stylus input configuration: The portable computer is open        with screen up in normal viewing position; but the bottom side        (opposite to the keyboard) of the base is up and used as input        pad.    -   (5) Space saving configuration: The portable computer is closed        with the display stacked underneath the base, so that the base        can be used as a desktop machine together with a desktop display        unit, typically with a bigger and better screen.    -   (6) Desk note configuration: The display is completely detached        from the base so that the base can be used as a desktop machine        together with a desktop display unit. (Both this configuration        and the Space saving configuration can get the built-in display        out of the way of the desktop monitor screen.)    -   (7) Flexible display orientation configuration: The display        screen supports both portrait and landscape viewing        orientations.

There have been numerous attempts to support various subsets of theseseven configurations. Many of them are focused on the screen viewingposition adjustment using various approaches, which are all differentfrom the multi-sectioned arm approach in the present invention. Someothers are focused on mode transitioning between conventional notebookand tablet PC. There has been no single invention until now that cansolve all seven configurations in a single computer.

The purpose of the present invention is to devise a basic mechanism forsupporting all or a select subset of configurations (1)-(7) in onesingle portable computer.

SUMMARY

The present invention supports, in one single portable computer, all ora subset of configurations (1)-(7) as specified in the BackgroundSection.

A portable computer according to the present invention generallyincludes a computer base and a display, which are connected togetherthrough one or more multi-sectioned arms. Such a multi-sectioned armincludes rotatably linked sections; and it may also include extendablyand contractibly linked sections. The electronic and electric wiringcable between the base and the display can run completely inside one ormore of the arms. The wiring cable can also run separately without goingthrough the arm (or arms); and in this case, a retractable cable may beused.

The connection linking each arm to the display (and similarly, the base)can either be a pivotal hinge (connection pivot) or a mounting mechanismsuch as a tunnel to receive an end section of the arm. In either case,the screen's viewing angle can be adjusted, either by rotating thedisplay around the connection pivots (if any), or by turning some of thearm sections relatively to each other.

The arms can be folded and parked alongside the portable computer inclosed positions. At the conventional screen viewing position, thefolded arms can be turned away so that they do not block the computerbase's edges for other uses, such as DVD, network card, and otheroutlets.

The arms can also be flexibly stretched to allow continuous adjustmentof the screen's spatial position by height (up or down relative to thebase), depth (forward or backward relative to the base's user edge), andwidth (left or right away from space above the base). The screen canalso be tilted left and right. (See configurations (1) and (2) in theBackground section.)

To see the range of screen position adjustment, consider the position ofthe middle point of the lower edge of the display, relative to the backedge of the base. In the conventional clam shell design (as shown inFIG. 5), this mid-point travels along a pre-determined curve with asemi-diameter about the height of the hinge connection between the baseand the display. In contrast, a portable computer of the presentinvention allows such a mid-point to be positioned at any position in a3-dimensional range with a diameter about the height of the fullystretched multi-sectioned arm.

By rotating the arm sections and by arranging how the display and thebase face each other the portable computer can be set to Configurations(1)-(5). The display can also be set to Configuration (7), i.e.,landscape and portrait viewing orientations, and even some slantedorientation. The arms can be detached completely from both the computerbase and the display. This not only allows for the computer to be setfor the desk note configuration (6), but also makes the arms replaceableor substitutable. Alternatively, some of the configurations can beobtained by detaching the arms, rearranging the arms, the display, andthe base, and then re-attaching the arms (if necessary).

Either friction mechanisms or locking mechanisms can be used at thejoints and the connection pivots (if any) to keep the arm sections, thebase, and the display in their chosen relative positions. There aremechanisms at the joints and the connection pivots to limit how much theattached arm sections can rotate or turn. (This can prevent potentialwiring and other damages from unlimited rotating and turning.) There arealso locking mechanisms to secure each arm's connections to the base andthe display.

For illustration, several embodiments of the computer according to thisinvention are presented, based on the numbers of arms and sections ineach arm as well as how the each arm is connected to the computer baseand the display. First, for simplicity of presentation, drawings ofthese embodiments are done using several notations representing basicparts such as arm sections and ways for linking them, assuming thesenotations can be implemented mechanically based on current mechanicalmanufacturing capabilities in the field. Then we provide detailedmechanical mechanisms for the implementations of these basic parts.Last, a preferred embodiment of a portable computer according thepresent invention is presented to show how the mechanical mechanisms canbe used together.

Typically, the computer base has two sides and four edges: the keyboardside, the bottom side (opposite to the keyboard), the left edge, rightedge, the front edge (user edge), and the back edge. The display alsohas two sides and four edges: the screen side, the back side (oppositeto the screen), the left and right edges, and the upper and lower edges(from the user's point of view). (Note: These features of the base andthe display are listed for convenience in the presentation. The presentinvention is not limited to portable computers having exactly thesefeatures.)

In the first embodiment, one single multi-sectioned arm is connected tothe back edges of the base and the display. In the second embodiment,two double-sectioned arms connect the base and the display by their sideedges, with one on the left and the other on the right. The thirdembodiment is an extension of the second embodiment by replacing thetwo-sectioned side arms with side arms using combo-joints, thus enablingthe display to move sideways (left and right relative to the base). Inthe fourth embodiment, a bridge arm anchors on the left and the rightedges of the computer base, and connects to the lower edge of thedisplay. The fifth embodiment is an extension of the second embodimentby using triple-sections arms (to show that it is possible to use sidearms of more than two sections). In the presentations of theseembodiments, some simple variations are also mentioned.

Some basic mechanical mechanisms are presented to implement themulti-sectioned arms and connection pivots, including severalembodiments of two mechanical friction joint mechanisms, a method forinstalling a wiring cable inside a multi-sectioned arm when using acable that is already pre-connected with connectors at its ends, andattachment mechanisms for connecting the arm to the display and thebase. Specifically, the mechanical friction joint mechanisms for armsection joints and connection pivots contain friction discs placed inclose contact with each other for friction generation. When the linkedparts rotate relatively, some discs engage and rotate in sync with oneof the parts in one direction, while the rest of the discs rotate in theopposite direction. The discs rotating relatively in opposite directionsare interposed, so their rotational friction collectively contributes tothe friction of the joint mechanisms. Also, a wiring cable can passthrough such a joint mechanism without interfering with the relativerotation of the friction discs. More details of the mechanicalstructures of the mechanisms will be described later.

It is worth mentioning that the mechanical mechanisms and methodpresented in this invention also address the following practical andmanufacturing issues:

-   -   Minimal changes (if any at all) to conventional portable        computer base and display enclosures and their connecting cable:        For example, the multi-sectioned arms can simply be attached        somewhere on the edges and sides of the base and the display;        and there is basically no change to the base and the display        (inside or outside).    -   Portability of the same arm (design) to a wide variety of        portable computers: For example, the friction joint mechanisms        according to the present invention enable scalable levels of        friction by varying the number of friction discs in the joint        during installation. This allows the same arm design to be        portable to different displays.

In summary, all or a subset of configurations (1)-(7) can be supportedin one single computer with multi-sectioned arms according to thepresent invention. This invention also presents mechanical mechanisms tobuild the arms, and ways to assemble such a computer (especially byadopting the base and the display as well as their connecting cable of aconventional portable computer).

BRIEF DESCRIPTION OF THE DRAWINGS Drawing Notations

FIG. 1 is a list of notations used in the drawings to represent one ofthe sections in a multi-sectioned arm in various scenarios.

FIG. 2 is a list of notations used in the drawings to show the relativemovements of the arm sections that are linked together.

FIG. 3 is a list of notations in various scenarios an arm can beattached to and detached from the base and the display.

FIG. 4 lists the base and the display of a portable computer. In thedrawings of all the embodiments, the base and the display will alwaysuse the same labels. (FIG. 4A denotes the display of a portablecomputer. FIG. 4B denotes the base of a portable computer.)

FIG. 5 is a perspective view of a conventional clam shell enclosuredesign of a portable computer, in an open position.

FIRST EMBODIMENT

FIG. 6A is a perspective view of the first embodiment of the computer(100) of the present invention with a single back multi-sectioned arm,in a partially open position.

FIG. 6B is a split view of the top portion of the arm connected to thedisplay of computer 100.

FIG. 6C is a possible substitute for the top portion of computer 100 asshown in FIG. 6B.

FIG. 6D is a simpler variation of a single arm portable computer of thepresent invention.

FIG. 6E is yet another variation by modifying the arm in FIG. 6D toenhance stability.

FIG. 6F is a variation of computer 100 to support both portrait andlandscape orientations of the display.

FIG. 6G is a perspective view of the computer in FIG. 6F when thedisplay is set to the portrait orientation.

FIG. 7 is a perspective view of computer 100 in a closed position.

FIG. 8 is a perspective view of computer 100 in a conventionally openedscreen-up position, with the folded arm placed next to the base's rightback edge 82 (from the user's point of view).

FIG. 9 is a perspective view of computer 100 in a conventionally opened,screen-up position, with the folded arm placed next to the base's leftback edge 82 (from the user's point of view).

FIG. 10 is a perspective view of computer 100 in a conventionallyopened, screen-up position, with the folded arm placed away from thebase's back edge 82.

FIG. 11 is a perspective view of computer 100 in a position where thedisplay is up-lifted, screen facing the user, and the arm being awayfrom the back edge 82 of the base.

FIG. 12 is a perspective left side view of computer 100 in an opened,screen-up position, where the screen is away from its conventionalvertical position towards the user.

FIG. 13 is a perspective view of computer 100 in an opened, screen-upposition, where arm sections 132 and 133 are positioned near the backedge 82 of the base.

FIG. 14 is a perspective view of computer 100 in an opened, screen-upand backward facing position, where arm sections 132 and 133 arepositioned near the back edge 82 of the base.

FIG. 15 is a perspective view of computer 100 in a closed position withviewing screen 98 facing upward (for the tablet PC configuration).

FIG. 16 is a perspective view of computer 100 in an open position inwhich the viewing screen 98 is facing the front, and the whole displayis lifted and positioned towards to the right edge of the user (suitablefor view sharing.)

FIG. 17 is a perspective view of computer 100 in a closed position withthe base sitting on top of the display (for the space-savingconfiguration).

SECOND EMBODIMENT

FIG. 18A is a perspective view of the portable computer (200) of thesecond embodiment of the present invention with two double-sectionedside arms. It is in a position where the screen is lifted and facing theuser.

FIG. 18B shows that the pair of arms 231 and 232 in computer 200 can besubstituted by another pair of arms 231B and 232B.

FIG. 18C shows that the pair of arms of computer 200 can also besubstituted with yet another pair of arms.

FIG. 19 is a perspective view of computer 200 in a closed, arms foldedposition. It also shows how the arms can be detached.

FIG. 20A is a perspective view of computer 200 in conventional openposition.

FIG. 20B shows a variation of computer 200.

FIG. 21 is perspective side view of computer 200 in a position with thescreen up-lifted and facing the user.

FIG. 22 is a perspective side view of computer 200 in a conventionalopen position with arms folded and lifted up to avoid blocking side edge84 of the base for other uses such as a DVD player and other outlets.

FIG. 23 is a perspective side view of computer 200 in an unconventionalopen position with arms partially stretched to reach behind the backedge of the base. (This is to show how flexible the display's viewingposition can be.)

FIG. 24 is a perspective side view of computer 200 in an open positionwith display 90 up-lifted and the keyboard faced down (for the stylusconfiguration (4)).

FIG. 25 is a perspective side view of computer 200 in a conventionalclosed position with arms folded and screen facing the keyboard.

FIG. 26 is a perspective side view of computer 200 in a closed positionwith arms folded, screen facing up, and the base stacked underneath thedisplay. (This is a version of the tablet PC configuration.)

FIG. 27 is a perspective side view of computer 200 in a closed positionwith arms folded and screen facing up. (This is an alternative design tosupport the tablet PC configuration. In this special design, the lengthof arm 232 can not exceed the length of side edge 84.)

THIRD EMBODIMENT

FIG. 28A is a perspective view of a portable computer (300) of the thirdembodiment of the present invention.

FIG. 28B is a split view of arms 231 and 232 of computer 200 and analternative pair of arms. Substituting the arms leads to the thirdembodiment of the present invention as shown in FIG. 28A.

FIG. 29 is a perspective view of portable computer 300 in a closedposition, with the arms folded.

FIG. 30 is a perspective view of portable computer 300 in a conventionalopen position, with arms folded and parked alongside the edges of thebase (80).

FIG. 31 is a perspective view of portable computer 300 in an openposition, with arms folded and reached out from the back of thecomputer.

FIG. 32 is a perspective view of portable computer 300 in an openposition, with arms folded, reached out first from the back of thecomputer, and then turned sideway away from the computer.

FIG. 33 is a perspective view of portable computer 300 in an openposition, with arms partially stretched, and with the display partiallyup-lifted and reached out towards the right hand side of the computer(from the user's point of view.)

FOURTH EMBODIMENT

FIG. 34A is a perspective view of the portable computer (400) of thefourth embodiment of the present invention. This embodiment has onemulti-sectioned bridge arm. It is in a position where the screen islifted and facing the user.

FIG. 34B shows is a partial view of a variation that replaces thedisplay and the bridge arm of computer 400.

FIG. 34C shows a variation of computer 400. In the variation, the bridgearm connects to the back edge of the base and to the left and rightedges of the display.

FIG. 35 is a perspective view of computer 400 in the conventional openposition.

FIG. 36 is a perspective view of computer 400 in the conventional closedposition.

FIG. 37 is a perspective view of computer 400 in an open position withthe arm folded and the screen facing away from the user.

FIG. 38 is a perspective view of computer 400 in a closed position withscreen facing upward.

FIG. 39 is a perspective view of computer 400 when the arm is completelydetached from base 80 and display 90.

FIFTH EMBODIMENT

FIG. 40A is perspective view of the portable computer (500) of the fifthembodiment of the present invention. This embodiment has twotriple-sectioned side arms. It is in a position where the screen islifted and facing the user.

FIG. 40B shows a variation by adding a horizontal section that connectsthe left and the right arms in computer 500.

FIG. 41A is a perspective side view of computer 500.

FIG. 41B is a perspective side view of computer 500 in a position wherethe screen is lifted and facing the user, and the keyboard is facingdown. (This is for the stylus input configuration.)

FIG. 42 is a perspective side view of computer 500 in a conventionalclosed position with arms folded.

FIG. 43 is a perspective side view of computer 500 in a closed positionwith arms folded and screen facing up (for the tablet PC configuration).

FIG. 44 is a perspective side view of computer 500 in a closed positionwith arms folded, base sitting on top of the display, and keyboardfacing up (for space saving when the portable computer is used as adesktop machine).

Basic Mechanical Mechanisms to Implement the Design Notations

FIG. 45 presents a groove and locking tip mechanism.

FIG. 46 shows some ways in which two arm sections can be rotatablyengaged together, either by direct engagement or by engagements withother intermediate parts. (For convenience, we also refer to such anengagement as “rotatably linked together”.)

FIG. 47 shows an embodiment of a friction joint (5000) of the presentinvention.

FIG. 48 shows a friction joint (5000A), which a variation of frictionjoint 5000.

FIG. 49 shows a friction joint (5000B), which is another variation offriction joint 5000.

FIG. 50 shows an embodiment of a friction joint (5100) of the presentinvention.

FIG. 51 shows an embodiment of a friction joint (5300) of the presentinvention

FIG. 52 shows an embodiment of a friction joint mechanism (5400) of thepresent invention. Such a mechanism can be built into the ends of amulti-sectioned arm for pivotally mounting the arm to the base or thedisplay of a portable computer (for example, computer 5200 in FIG. 62).

FIG. 53 shows an embodiment of a friction joint (5500) of the presentinvention.

FIG. 54 shows an embodiment of a friction joint (5600) of the presentinvention.

FIG. 55 shows an embodiment of a friction joint (5700) of the presentinvention.

FIG. 56 shows an embodiment of a friction joint (5800) of the presentinvention.

FIG. 57 shows an embodiment of a friction joint (5900) of the presentinvention.

FIG. 58 shows some ways in which arm sections directly linked tofriction joint 5000 can be extended.

FIG. 59 shows some ways in which mechanical joints 5000 and 5100 can becombined to create combo joints.

FIG. 60 presents a method for assembling multi-sectioned arms withembedded wiring cable when the cable used is pre-connected withconnectors at the ends.

FIG. 61 shows how to attach a multi-sectioned arm to the base or thedisplay of the portable computer of the present invention. This is amechanical implementation of the notation in FIG. 3A-FIG. 3D.

Putting it all Together

FIG. 62 shows a portable computer (5200). This is a mechanicalimplementation of the second embodiment of the portable computer (200)of the present invention with two double-sectioned side arms.

DETAILED DESCRIPTION OF THE PREFERRED AND ALTERNATIVE EMBODIMENTSDrawing Notations

For convenience in the drawings of the embodiments of the computeraccording to the present invention, FIG. 1-FIG. 3 list some notations asshort hands to represent arm sections, their linkage and relativemovements, and their connections to the base and the display. It shouldbe pointed out that only those used directly in the drawings are listedfor illustration purpose, and that they do not represent all thepossibilities enabled by the present invention.

FIG. 2 is a list of notations used in the drawings to show the relativemovements of the arm sections that are linked together.

FIG. 2A denotes a joint which allows the two attached sections to rotatearound the joint; and they rotate on two parallel planes.

FIG. 2B denotes a joint which allows the two attached sections to rotatearound the same axis; and they rotate on the same plane.

FIG. 2C denotes a joint which allows the two attached sections toindependently rotate around the joint on a common plane; and thesections will not overlap in a folded position. (The point of viewdictates which one of the two pictures to use in the drawings.)

FIG. 2D denotes a joint which allows the two attached sections to turnin relatively opposite direction.

FIG. 2E is perspective view of a combination of two joints and three armsections. The purpose is to show how simple joints can be combined toallow more flexible rotations of the end sections. Around joint 841, armsection 831 can rotate in any selected plane; and the selected plane canchange when arm section 832 turns (relative to arm section 833) aroundjoint 842. If we look at the combination as a whole, the end sections831 and 833 can turn independently on separate planes. That is, evenwhen arm section 833 stays still, arm section 831 can turn on its own ona selected plane; and furthermore, this selected plane can change evenwhen section 833 does not move. (In engineering implementation, if themiddle section 832 is short, it may help to think of such a jointcombination as just one combo-joint mechanism which allows the twoattached end sections 831 and 833 to rotate independently. Therefore, wealso have the notation of FIG. 2F.)

FIG. 2F denotes a joint which allows the two attached sections to rotateindependently around two separate axes, and they rotate on two separateplanes. There is more than one variation (two being shown here). Thepoint of view dictates which variation to use in a drawing. In general,this type of joint is marked by a block circle containing two of thethree symbols: a white vertical bar, a white horizontal bar, and a whitecircle, which are used to indicate the planes for the associated armsections to rotate on. We generally use the white horizontal bar toindicate the associated arm section that can rotate on a plane parallelto the base of the portable computer. We use the white vertical bar toindicate the associated arm section that can rotate on a plane that isperpendicular to the base of the computer, and that the plane isinvisible or reduced to a line from the perspective view point of thedrawing. And we use the white circle to indicate the plane that is alsoperpendicular to the base of the computer, but the plane is at leastpartially visible from the perspective view point of the drawing. (Thisnotation is somewhat analogous to the 3D coordinates. But it is not thesame because the three planes here do not have to be perpendicular toone another. In engineering implementation, this type of joint can besubstituted with a joint-combo such as FIG. 2E.)

FIG. 2G denotes a joint that allows arm section 835 to rotate aroundsection 834.

FIG. 2H denotes two or more arm sections that are extendably andcontractibly linked together to form a shortenable and elongatable armportion. The doubled-headed arrow indicates the directions in which thelinked sections can extend and contract. For convenience, these linkedsections together are referred to as the extendable sections and also asthe contractible sections. In engineering implementations, for example,such sections can be telescopically linked together; and they can alsobe slidably linked together.

FIG. 4A is a perspective view of the display of a portable computer inan upward position. Display 90 generally has two sides and four edges:viewing screen side 98, back side 97, upper edge 91, lower edge 92, leftedge 93, and right edge 94 (from the user's normal view point).

FIG. 4B is a perspective view of the base of a portable computer. Base80 preferably includes a central processing unit and other electroniccomponents and a data entry member, such as a keyboard. Base 80generally has two sides and four edges: upper side (keyboard) 87, bottomside 88, front or user edge 81, back edge 82, left edge 83, and rightedge 84 (from the user's normal view point). The bottom side 88 cansometimes be used by an alternative data entry member, such as stylusinput.

First Embodiment

FIGS. 6 to 17 show a portable computer (100) according to a firstembodiment of the present invention. Computer 100 has one single backarm.

FIG. 6A is a perspective view of the portable computer (100) of thefirst embodiment of the present invention. This embodiment includes adisplay 90, a base 80, and a multi-sectioned arm 130. One end section131 of the arm is connected to the display at pivot 151; and the otherend section 134 is connected to the based at pivot 152. Pivot 151 allowsthe display to rotate relatively around arm section 131; and pivot 152allows the base to rotate relatively to arm section 134. Consequentlythe portable computer can be arranged into various configurations bycontrolling how display 90 and base 80 face each other. (Alternatively,such configurations can be obtained by simply detaching the arms,setting up the display and the base to the desired configurations, andre-attaching the arms again.) Arm sections 132 and 133 can be adjustedindependently around joint 143, as assisted by joint 142 and joint 144(a function denoted as a white circle in the black circle),respectively. Together they allow the arm to control the continuousmovement of pivot 151 (and thus the screen) within a selected plane.Besides, this selected plane can be changed continuously using afunction of joint 141 (denoted as a horizontal white bar inside theblack circle), together with its counterpart in joint 144. Therefore,the viewing screen's position can be adjusted continuously within athree dimensional space of semi-diameter equal to the total length ofarm sections 132 and 133. The screen's viewing angle can be adjustedusing the other function of joint 141 (denoted as a vertical white bar).There are locks to prevent the end sections 131 and 134 fromunintentional detachment. There are also mechanisms to control how muchthe end sections of the arm can rotate at pivots 151 and 152,respectively.

FIG. 6B is the top portion the arm connected to the display of computer100. This portion can be substituted by an alternative version as shownin FIG. 6C. One function of joint 141 (as in FIG. 6B) is to tilt thescreen for different viewing angle; and this can be achieved by turningdisplay 90 at the “T-shaped” arm section 138 (as in FIG. 6C). Theability for the display to turn around the end section 131 (as in FIG.6B) can be achieved by turning the “T-shared” arm section at joint 147(as in FIG. 6C). And the function of joint 142 in assisting the armsection 132 to turn (as in FIG. 6B) can be achieved by a function ofjoint 148 (denoted as a white circle in the black circle, as in FIG.6C). And finally, one function of joint 141 as denoted by the horizontalwhite bar inside the black circle (as in FIG. 6B) can be achieved by thecounterpart in joint 148 (as in FIG. 6C).

FIG. 6D is a simpler variation of a single arm portable computer of thepresent invention. This arm is functionally less flexible than the armin computer 100. With this simpler arm, the display can move up anddown, and left and right, relative to the base. Since our focus at thispoint is to discuss computer 100 (FIG. 6A), we shall skip the detaileddiscussion of this variation. FIG. 6E is yet another variation bymodifying the arm in FIG. 6D to enhance stability.

FIG. 6F is a variation of computer 100. In this variation, 131 andconnection pivot 151 in FIG. 6A are replaced by sections 131 a and 131b, joint 140, and connection pivot 150 (on the back side of thedisplay). Notice that joint 140 serves the role previously served bypivot 151, and that the location connection 150 on the back of thedisplay allows the display to rotate between landscape and portraitorientations. FIG. 6G is a perspective back view when the screen is aportrait orientation.

FIG. 7 is a perspective view of computer 100 in a closed position. Thisposition can be obtained by folding arm 130 in FIG. 6A.

FIG. 8 is a perspective view of computer 100 in a conventionally opened,screen-up position, with the folded arm placed next to the base's rightback edge 82 (from the user's point of view). This position can beobtained by lifting the end section 131 around joint 141 in FIG. 7.

FIG. 9 is a perspective view of computer 100 in a conventionally opened,screen-up position, with the folded arm placed next to the base's leftback edge 82 (from the user's point of view). This position can beobtained by swinging the arm sections simultaneously around 141 and 144(using the functions denoted by the horizontal white bars inside theblack circles) in FIG. 8

FIG. 10 is a perspective view of computer 100 in a conventionallyopened, screen-up position, with the folded arm placed away from thebase's back edge 82 (to avoid blocking the back edge 82 of the base forother uses, such as various cable outlets.) This position can beobtained by swinging the arm simultaneously using the functions denotedby the horizontal white bars in 141 and 144 in FIG. 8.

FIG. 11 is a perspective view of computer 100 in a position where thedisplay is up-lifted, screen facing the user, and the arm being awayfrom the back edge 82 of the base. This position can be obtained byopening up arm 130 in FIG. 10.

FIG. 12 is a perspective left side view of computer 100 in an opened,screen-up position, where the screen is away from its conventionalvertical position towards the user. This position can be obtained byadjusting the rotation angles of 132 and 133 at joint 143 in FIG. 11.

FIG. 13 is a perspective view of computer 100 in an opened, screen-upposition, where arm sections 132 and 133 are positioned near the backedge 82 of the base. This position can be obtained by lifting the endsection 131 around joint 141 in FIG. 6A.

FIG. 14 is a perspective view of computer 100 in an opened, screen-upand backward facing position, where arm sections 132 and 133 arepositioned near the back edge 82 of the base. This position can beobtained from FIG. 8 by turning the screen to the back.

FIG. 15 is a perspective view of computer 100 in a closed position withviewing screen 98 facing upward (for the tablet PC configuration). Thisposition can be obtained by closing down the display from FIG. 14.

FIG. 16 is a perspective view of computer 100 in an open position inwhich the viewing screen 98 is facing the front, and the whole displayis lifted and positioned towards to the right side of the user (suitablefor view sharing.) This position can be obtained by moving display 90towards the right side (relative to the user) as shown in FIG. 13.

FIG. 17 is a perspective view of computer 100 in a closed position withthe base sitting on top of the display (for the space-savingconfiguration). This position can be obtained from FIG. 13 in thefollowing steps: Rotate base 80 around arm section 134 (connected atpivot 152) to let the keyboard face down; close the computer; and turnthe computer down-side-up.

Second Embodiment

FIGS. 18 to 27 show a portable computer (200) of a second embodiment ofthe present invention. Computer 200 has two double-sectioned side arms.

FIG. 18A is a perspective view of the portable computer (200) of thesecond embodiment of the invention. The computer has twodouble-sectioned side arms. It is in a position where the screen islifted and facing the user. The portable computer 200 generally includesa display 90, a base 80, and two double-sectioned side arms 231 and 232.The left arm 231 is connected to the display at pivot 251, and to thebase at pivot 253. The right arm 232 is connected to the display atpivot 252, and to the base at pivot 254. The viewing angle of the screencan be adjusted by rotating the display around pivot 251 and pivot 252.The double-sectioned arms can be adjusted synchronously through joints241 and 242, thus allowing continuous adjustment of the display'sposition by height and depth (see Configuration (1) in the Backgroundsection). The range of adjustment can be as far as the length of thefully stretched arms. The portable computer can be arranged into variousconfigurations by setting how the screen 98 and the keyboard 87 faceeach other; and this can be achieved by turning the base and displayaround the connection pivots (at 251, 252, 253, and 254). There arelocks to prevent the arms from unintentional detachment from the baseand the display. There are also mechanisms to control how much the endsections of the arm can turn at pivots 251, 252, 253, and 254.

FIG. 18B shows that the pair of arms (231 and 232) in computer 200 canbe substituted by another pair of arms (231B and 232B). Both 231B and232B have extendable sections at their ends.

FIG. 18C shows that the pair of arms of computer 200 can also besubstituted with yet another pair of arms.

FIG. 19 is a perspective view of computer 200 in a closed, arms foldedposition. It also shows how the arms can be detached. This position canbe obtained by turning the screen face down and then folding the arms.

FIG. 20A is a perspective view of computer 200 in conventional openposition.

FIG. 20B is a variation of computer 200. The arms (231B and 232B) haveextendable sections at their ends. The extendable sections allow each ofthe folded arms to adjust its distance from the edges of the base andthe display. This added feature of the arms is useful in certainsituations. For example, an external network card (for wired andwireless networking alike) of many of today's brands often leaves a bigportion of the card's body outside of the insertion slot; and theun-inserted portion of the card may interfere with the folded arm parkedby the edge of the base if the arm is too close to the edge.

FIG. 21 is perspective side view of computer 200 in a position with thescreen up-lifted and facing the user. It shows how the upper and lowersections of arm 232 can turn independently around joint 242. It alsoshows how the display can rotate around arm at 252 and how the arm canturn relatively around the base at 254. (The left arm is not shown inthis view.) These mechanisms allow the portable computer to transitionfrom its current position to any of the configurations as shown in FIG.24-FIG. 26.

FIG. 22 is a perspective side view of computer 200 in a conventionalopen position with arms folded and lifted up to avoid blocking the edge84 of the base for other uses (such as a DVD player).

FIG. 23 is a perspective side view of computer 200 in an unconventionalopen position with arms partially stretched to reach behind the backedge of the base. (This is to show how flexible the display's viewingposition can be.)

FIG. 24 is a perspective side view of computer 200 in an open positionwith display 90 up-lifted and the keyboard faced down (for the stylusconfiguration (4)). This position can be obtained from FIG. 21 by twosteps: turn the base around pivot 254 to a face-down position; and thenadjust 232.

FIG. 25 is a perspective side view of computer 200 in a conventionalclosed position with arms folded and screen facing the keyboard.

FIG. 26 is a perspective side view of computer 200 in a closed positionwith arms folded, screen facing up, and the base stacked underneath thedisplay. (This is for the tablet PC configuration.) This position can beobtained from FIG. 21 in the following steps: Flip the base to make thekeyboard face down (by rotating the base around pivot 254); fold the armtowards the right hand side in FIG. 21 (i.e. in the opposite directionto how the arm is normally opened and closed in the notebookconfiguration); and close down display (with screen facing up).

FIG. 27 is a perspective side view of computer 200 in a closed positionwith arms folded and screen facing up. (This is an alternative design tosupport the tablet PC configuration. In this special design, the lengthof the arm 232 should not exceed the length of side edge 84.)

Third Embodiment

FIGS. 28 to 33 show a portable computer (300) of a third embodiment ofthe present invention. The third embodiment is an enhancement of thesecond embodiment by substituting the side arms in computer 200 with anenhanced pair of arms, in order to allow the display to move left orright relative to the base.

FIG. 28A is a perspective view of a portable computer (300) of the thirdembodiment of the present invention. The third embodiment is anextension of the second embodiment by substituting the side arms (231and 232) in computer 200 with a different pair of arms as shown in FIG.28B. Each of these new arms has two additional combo-joints 341 and 345(also 342 and 346 on the other arm). The additional joints allow themiddle sections of the arms to swing away from the side edges of thecomputer (300), and consequently enabling the display to move sideway,as shown in FIG. 33. This swinging movement uses the functions of thejoints denoted by white horizontal bars inside the black circles (joints341, 345, 342, and 346). And the white circles inside the black circlesare for cooperation with middle joints 343 and 344 in folding andstretching of the long sections (333, 335, 334, and 336). In addition tosideway movement for the display (or adjustment by width as specified inConfiguration (2) of the Background Section), computer 300 of the thirdembodiment retains all the allowable positions and configurations ofcomputer 200 of the second embodiment.

FIG. 28B is a split view of arms 231 and 232 of computer 200 (as shownin FIG. 18A) and an alternative pair of arms. Substituting the armsleads to the third embodiment of the present invention as shown in FIG.28A.

FIG. 29 is a perspective view of portable computer 300 in a closedposition, with the arms folded.

FIG. 30 is a perspective view of portable computer 300 in a conventionalopen position, with arms folded and parked alongside the edges of thebase (80).

FIG. 31 is a perspective view of portable computer 300 in an openposition, with arms folded and reached out from the back of thecomputer. This position can be obtained from FIG. 28A by folding thearms (around joints 343 and 344) in the opposite direction from the waythey are normally folded when the computer is in a conventional closeposition as shown in FIG. 29.

FIG. 32 is a perspective view of portable computer 300 in an openposition, with arms folded, reached out first from the back of thecomputer, and then turned sideway away from the computer. This positioncan be obtained from FIG. 31 by turning the middle sections 333 and 335around joints 341 and 345 on one arm, respectively (and also sections334 and 334 around joints 342 and 346 on the other arm, respectively).This position places the sections 333 and 335, and 334 and 336 all onthe same plane. This is a preparation for the position in FIG. 33.

FIG. 33 is a perspective view of portable computer 300 in an openposition, with arms partially stretched, and with the display partiallyup-lifted and reached out towards the right hand side of the computer(from the user's point of view.) This position can be obtained from FIG.32 by moving the arms sections simultaneously, 333 and 345 on one arm,and 344 and 346 on the other; and this simultaneous movement is possiblewhen these four arm sections are on the same plane, a condition set upin FIG. 32.

Fourth Embodiment

FIG. 34-FIG. 39 show a portable computer (400) according to a fourthembodiment of the present invention. Computer 400 has a bridge arm.

FIG. 34A is a perspective view of the portable computer (400) of thefourth embodiment of the present invention. This embodiment has onemulti-sectioned bridge arm. It is in a position where the screen islifted and facing the user. The portable computer 400 generally includesa display 90, a base 80, and a multi-sectioned bridge arm 430. Thebridge arm sections 433 and 434 are attached to the based at pivots 451and 452, respectively; and the middle section 439 is connected to thedisplay at pivot 450. The viewing angle of the screen can be tilted byturning arm section 439 relatively to joints 441 and 442. The screen canrotate around pivot 450. Upper side arm sections 431 and 432 (similarlylower side arm sections 433 and 434) are adjustable synchronously.Adjusting the side arm sections allows continuous adjustment of thedisplay's position by height and depth (Configuration (1) of theBackground Section). The range of adjustment is limited by the lengththe side arm sections. The portable computer can be arranged intovarious configurations by setting how the screen 98 and the keyboard 87face each other. There are locks to prevent the arms from unintentionaldetachment from the base and the display. (FIG. 39 shows how the arm canbe completely detached from the base and the display.) There are alsomechanisms to control how much the end sections of the arm can turn atpivots 451, 452, 453, and 454.

FIG. 34B is a partial view of a variation that replaces the display andthe bridge arm of computer 400.

FIG. 34C shows a variation of computer 400. In the variation, the bridgearm connects to the back edge of the base and to the left and rightedges of the display.

FIG. 35 is a perspective view of computer 400 in the conventional openposition.

FIG. 36 is a perspective view of computer 400 in the conventional closedposition.

FIG. 37 is a perspective view of computer 400 in an open position withthe arm folded and the screen facing away from the user. This positioncan be obtained from FIG. 35 by turning the display around the attachedarm section at pivot 450.

FIG. 38 is a perspective view of computer 400 in a closed position withscreen facing upward. This position can be obtained from FIG. 37 byclosing down the display.

FIG. 39 is a perspective view of computer 400 when the arm is completelydetached from base 80 and display 90. (For example, one possible way tomake this bridge arm detachable from the base in this case is to useextendable sections (see FIG. 2H) at the ends that connect to the base.

Fifth Embodiment

FIG. 40 to FIG. 44 show a portable computer (500) according to a fifthembodiment of the present invention. Computer 500 is an enhancement ofcomputer 200 by adding an additional section to each of the two sidearms. The purpose is to show that it is possible to have side arms withmore than two sections.

FIG. 40A is a perspective view of computer (500) having twotriple-sectioned side arms. It is in a position where the screen islifted and facing the user. The portable computer generally includes adisplay 90, a base 80, and two triple-sectioned side arms attached tobase and the display on their left and right sides. The adjustability ofthe display and the allowable configurations of this portable computerare similar to those of portable computer 200. FIG. 41A shows how thearm sections, joints, and pivots can be adjusted. It allows the portablecomputer to transition from its current position to a variety of thepositions shown in FIG. 41B-FIG. 44.

FIG. 40B shows a variation by adding a horizontal section that connectsthe left and the right arms in computer 500. This turns the two separatearms into a single bridge arm that connects the left and right edges ofthe base and the display. In practical application, this addedhorizontal section may enhance the stability of arm structure.

FIG. 41A is a perspective side view of computer (500).

FIG. 41B is a perspective side view of computer 500 in a position wherethe screen is lifted and facing the user; and the keyboard is facingdown. (This is for the stylus input configuration.) This position can beobtained from FIG. 41A by the following steps: turn the base aroundpivot 554; stretch the lower two sections of arm and then partially foldthem back in the opposite direction around joint 544; turn the displayaround pivot 552.

FIG. 42 is a perspective side view of computer 500 in a conventionalclosed position with arms folded.

FIG. 43 is a perspective side view of computer 500 in a closed positionwith arms folded and screen facing up (for the tablet PC configuration).

FIG. 44 is a perspective side view of computer 500 in a closed positionwith arms folded, base sitting on top of the display, and keyboardfacing up (for space saving when the portable computer is used as adesktop machine).

Notice that up to this point, we have presented embodiments as well asvariations of the portable computer of the present invention with armsthat have various numbers of arm sections and that connect to a numberof combinations of the edges and sides of the base and the display. Itshould become obvious that other embodiments with arms designed in suchways to connect to other combinations of edges and sides of the displayand the base can easily be worked out. Therefore, there is no need toenumerate more variations.

Locking Mechanisms and Rotatable Connections

FIG. 45 presents a groove and locking tip mechanism for preventing tworotatably linked sections from detaching and for limiting the relativerotation of the two linked sections within a pre-determined range.

FIG. 45A presents a C-shaped groove and locking tip mechanism 1200. Theouter surface of cylinder 1211 has a C-shaped groove 1291. The innersurface of cylinder 1212 has a tip 1292. The diameter of the cylinder1211 is slightly smaller than the inner diameter of cylinder 1212, sothat 1211 can be inserted into 1212. When 1211 is fully inserted into1212, tip 1292 is engaged with groove 1291. Tip 1292 only yields topressure from the back, and therefore allows the insertion of cylinder1211 into cylinder 1212. Tip 1292 does not yield to pressure from otherdirections. Therefore, groove 1291 and tip 1292 together provide twofunctions: (1) to prevent cylinder 1211 from backing out of cylinder1212, as shown in FIG. 45B, and (2) to limit the rotation of 1211 within1212 in a pre-determined range, as shown in FIG. 45C. The tip 1292 andgroove 1291 can be implemented in manner known per se by a personskilled in the art, for which reason they will not be described ingreater detail here.

FIG. 45B is a sectional view of mechanism 1200.

FIG. 45C is another sectional view of mechanism 1200.

FIG. 46 shows several ways in which two arm sections can be rotatablyengaged together, either by direct engagement as in FIG. 46A, or byengagements with other intermediate parts as in FIG. 46B or FIG. 46C. InFIG. 46B, both the sections on the left and right are engaged withintermediate part 5091. In FIG. 46C, 5092 a and 5092 b are rotatablymounted together; and 5092 a will be inserted into the object on theleft and 5092 b to the object on the right. A locking (or securing)mechanism can be added to keep the linked arm sections from disengaging.For example, the locking mechanism can be a groove and tip mechanism asin FIG. 45; and in the case of FIG. 46C, a simple locking tip, a latch,a screw, or even superglue can be used to keep parts 5092 a and 5092 bfrom retreating from the inserted positions inside the left and rightarm sections, respectively.

Friction Joint Mechanisms

In the figures (FIG. 47-FIG. 57) illustrating embodiments of thefriction joint mechanisms of the present invention, we focus on thedetails of the friction mechanisms of the joints. We do not enumeratevarious ways for linking the arm sections, and engagement securing orlocking mechanisms that can be applied, because both of these can behandled by people skilled in the art. For simplicity of presentation anddrawing, we assume that an appropriate means including the ones listedabove is used to prevent the linked parts from disengaging. Furthermore,the external shapes of the two linked hollow objects in the embodimentsare for illustration purpose only; other external shapes are possible solong as the objects can be rotatably linked together.

Before presenting specific details of various embodiments of themechanical friction joint mechanisms of the present invention, it wouldbe helpful to discuss the general mechanisms first. FIG. 47-FIG. 55illustrate a number of embodiments of a friction joint mechanism of thepresent invention for rotatably linking two hollow objects, a firstobject and a second object. These two objects can be two arm sections;and as shown in FIG. 52, they can also be an end section of an arm and aconnection pivot that is built into the arm for mounting to the base orthe display of a portable computer (for example, computer 5200 in FIG.62). This friction joint mechanism allows the two linked objects torotate relatively around a common axis. Along the rotation axis, thereis a shaft with a deformed small diameter portion inserting into twogroups of discs by the insertion holes on the individual discs. Referredto as the first group and the second group for convenience, each groupincludes one or more discs; and the discs of the first group areinterposed with the discs of the second group. The discs are placedclosely for frictional contact with one another. A fastening means suchas a screw (or a screw nut) and optionally an elastic means such as aspring washer (or disc spring) are provided to tighten the frictionalcontact of the discs. The shaft is either a portion of the first object(as in the case of FIG. 55) or a separate piece that is firmly mountedto first object (as in FIG. 47-FIG. 54). The disks along with theirengaged portion of the shaft are held inside the second object. Thediscs have such sizes and shapes, and they are mounted on the shaft andinside the second object in such a way that, when the first objectrotates relatively to the second object, the first group of discsrotates in sync with the shaft and the second group of discs rotates insync with the second object. Therefore, the rotational friction betweenthe contacting discs of the two groups contributes to the friction ofthe joint mechanism. Furthermore, this friction joint mechanism allows awiring cable to run from the inside of the first object to the inside ofthe second object, without leaving the enclosure of joint mechanism. Inthe embodiments illustrated in FIG. 47-FIG. 54, the wiring cable doesnot insert into the discs; and these embodiments vary slightly in howthe two linked objects are angled relative to the rotation axis, forexample, parallel to or perpendicular to the rotation axis. In theembodiment in FIG. 55, the shaft is a portion of the first object; andin this case, the wiring cable runs directly from the inside of thefirst object into the inside of the second object; and consequently thewiring cable indirectly inserts into the discs.

FIG. 56-FIG. 57 illustrate two embodiments of another friction jointmechanism of the present invention for linking two hollow objects, afirst object and a second object. These two objects can be arm sections.This mechanism allows the objects to rotate around two parallel axes, afirst axis and a second axis. Along the first and second rotation axes,there are two shafts, respectively referred to as the first shaft andthe second shaft. These two shafts can be portions of the two linkedobjects (as in the case of FIG. 57); and they can also be separatepieces firmly mounted to the respective objects (as in FIG. 56). Thejoint mechanism also includes three groups of discs, a first group, asecond group, and a third group. Each group has one or more discs. Eachof the discs in the first and the second groups has an insertion hole;while each of the discs in the third group has a pair of insertionholes. A deformed small diameter portion of the first shaft inserts intothe first group of discs by their insertion holes; and a deformed smalldiameter portion of the second shaft inserts into the second group ofdiscs by their insertion holes. In addition, the two shafts both extendthrough each pair of insertion holes of the discs in the third group.The discs in the third group are interposed with the discs of the firstgroup on the first shaft, and interposed with the discs of the secondgroup on the second shaft. The discs are placed closely for frictionalcontact with one another. A fastening means such as a screw andoptionally an elastic means such as a spring washer are provided totighten the frictional contact of the discs on each shaft. The discs ofthe first and second groups have such sizes and shapes, and they arerespectively mounted on the first and the second shafts in such a waythat, when the first and second linked objects respectively rotatearound the two rotation axes, the first group of discs rotates in syncwith the first shaft, and the second group of discs rotates in sync withthe second shaft; however, the third group of discs does not rotatearound either of the two axes. Therefore, the rotational frictionbetween the first and third groups of discs and the rotational frictionbetween the second and third groups of discs contribute to the frictionof this joint mechanism. Optionally, an enclosure can added to house thethree groups of discs as well as their engaged portions of the twoshafts. Furthermore, this friction joint mechanism allows a wiring cableto run from the inside of the first object to the inside of the secondobject, without leaving the enclosure of joint mechanism. In theembodiment illustrated in FIG. 56, the wiring cable does not insert intothe discs. In the embodiments illustrated in FIG. 56-FIG. 57, the twolinked objects are angled perpendicular to the two rotation axes.

We now describe the mechanical implementation of the friction jointmechanisms of the present invention in more specific details.

FIG. 47 shows an embodiment of a friction joint (5000) of the presentinvention.

FIG. 47A is an exploded view of the friction joint mechanism. The twohollow objects linked together are 5033 and 5034. 5080 is a shaft thatis firmly mounted inside 5033; and at the portion (5080 a) for mounting,a pass way is reserved for the wiring cable to bypass the frictionmechanism. Spring washer 5010 and screw 5020 are included for tighteningthe frictional contact of the discs, as shown in FIG. 47E.

FIG. 47B shows that the shaft has a deformed small diameter portion 5080c with screw thread at the end. There are two groups of discs, 5050 and5060, which are interposed.

FIG. 47C shows the cross section views of the deformed small diameterportion of shaft and the discs in group 5050 and 5060. A disc in group5050 has a circular edge and a deformed insertion hole that matches thedeformed shape of small diameter portion 5080 c. A disc in group 5060has a circular insertion hole and a shape that matches the shape ofcavity 5034 a. Because the matching of the shapes (and sizes), when 5033and 5034 rotate relatively to each other, the discs in group 5050 rotatein sync with 5033, and discs in group 5060 rotate in sync with 5034.

FIG. 47D is a perspective view of the joint when 5033 and 5034 rotatablylinked together. FIG. 47E is a sectional view of the joint; it shows howthe discs of groups 5050 and 5060 are interposed with frictional contacttightened by spring washer 5010 and screw 5020, engaged with shaft 5080,and held inside 5034. Dashed line 5070 shows how a wiring cable can runfrom the inside of 5033 to the inside of 5034, bypassing the discs, thespring washer, and the screw using pass way 5071, without leaving theenclosure of the joint mechanism.

FIG. 47E shows that simple variations are possible by altering the shapeof the discs in group 5060 and the shape of the cavity in 5034.

FIG. 48 shows a friction joint (5000A), which is a slight variation offriction joint 5000 by adding an intermediate part (5091) for engaging5033 and 5034. The rest of the details are similar to FIG. 47. FIG. 48Ais an exploded view; FIG. 48B is a perspective view; and FIG. 48C is asectional view.

FIG. 49 shows a friction joint (5000B), which is another slightvariation of friction joint 5000. In this variation, 5033 and 5034 areengaged indirectly by engaging with the shaft and the discs. To securethe engagement, cap 5090 is mounted on object 5034 to prevent the discsfrom backing out the insertion inside 5034. The rest of the details aresimilar to FIG. 47. FIG. 49A is an exploded view; FIG. 49B is aperspective view; and FIG. 49C is a sectional view.

FIG. 50 shows an embodiment of a friction joint (5100) of the presentinvention. The two linked hollow objects are 5133 and 5134. FIG. 50A isan exploded view; FIG. 50B is a different perspective view of 5133. FIG.50C is a perspective view of the joint; and FIG. 50D is a sectionalview. The basic idea here is the same as that of friction joint 5000(FIG. 47); and for those components that are the same as in FIG. 47,such as the discs, the spring washer, and the screw, we use the samelabels. There are a few minor differences. Here, the shaft (5180),firmly mounted on 5133, is perpendicular to 5133. For variation, wechoose different external shapes for 5133 and 5134; and it would notaffect the functionality of the joint if they had circular externalshapes. Dashed line 5170 shows how a wiring cable can run from theinside of 5133 to the inside of 5134, bypassing the discs, the springwasher, and the screw using pass way 5171, without leaving the enclosureof the joint mechanism. Notice here how the cable can go around theshaft (5180) inside 5133.

FIG. 51 shows an embodiment of a friction joint (5300) of the presentinvention. FIG. 51A is an exploded view; FIG. 51B is a perspective view;and FIG. 51C is a sectional view. The two linked hollow objects are 5333and 5334. The basic idea here is the same as that of friction joint 5000(FIG. 47) except that the wiring cable here does not need to bypass thefriction mechanism using a pass way in 5334, because as the cable entersthe joining portion, it goes in the opposite direction of the frictionmechanism residing in portion 5334 a. For those components that are thesame as in FIG. 47, such as the discs, the spring washer, and the screw,we use the same labels. There are a few other minor differences. Here,the shaft (5380) is perpendicular to the extended portion of 5334. Forvariation, we choose a different external shape for the extended portionof 5334; and it would not affect the functionality of the joint if ithad a circular external shape. Dashed line 5370 shows how a wiring cablecan run from the inside of 5333 to the inside of 5334, without leavingthe enclosure of the joint mechanism. Notice here how the cable can goaround the shaft (5380) inside 5333.

FIG. 52 shows an embodiment of a friction joint mechanism (5400) of thepresent invention. Such a mechanism can be built into the ends of amulti-sectioned arm for pivotally mounting the arm to the base and thedisplay of a portable computer (for example, computer 5200 in FIG. 62).The two linked objects are 5433 and 5441. FIG. 52A is an exploded view;FIG. 52B is a different perspective view of 5433. FIG. 52C is aperspective view of the joint; and FIG. 52D is a sectional view. Thebasic idea here is the same as that of friction joint 5100 (FIG. 50)except that the wiring cable here does not need to bypass the frictionmechanism using a pass way in 5441, because the cable exits 5441 at hole5471. For those components that are the same as in FIG. 50, such as thediscs, the spring washer, and the screw, we use the same labels. Dashedline 5470 shows how a wiring cable can run from the inside of 5433 tothe inside of 5441, and exit at insertion hole 5471 (potentiallyentering another object, such as the display or the base of the portablecomputer of the present invention). Notice here how the cable can goaround the shaft (5480) inside 5433.

FIG. 53 shows an embodiment of a friction joint (5500) of the presentinvention. The two linked objects are 5533 and 5534. FIG. 53A is anexploded view; FIG. 53B is a different perspective view of 5533. FIG.53C is a perspective view of the joint; and FIG. 53D is a sectionalview. The basic idea here is the same as that of friction joint 5100(FIG. 50). For those components that are the same as in FIG. 50, such asthe discs, the spring washer, and the screw, we use the same labels.There are a few minor differences. The extended portions of the 5533 and5534 are parallel to each other; and they are placed on the same side ofthe friction mechanism; and this allows the wiring cable (5570) to runfrom the inside of 5433 to the inside of 5534, without having to bypassthe friction mechanism in portion 5434 a. Notice here how the cable cango around the shaft (5580) inside 5333.

FIG. 54 shows an embodiment of a friction joint (5600) of the presentinvention. The two linked objects are 5633 and 5634. FIG. 54A is anexploded view; FIG. 54B is a different perspective view of 5633. FIG.54C is a perspective view of the joint; and FIG. 54D is a sectionalview. As far as the friction mechanism is concerned, the basic idea hereis the same as that of friction joint 5500 (FIG. 53). For thosecomponents that are the same as in FIG. 53, such as the discs, thespring washer, and the screw, we use the same labels. There is onenoticeable difference: the two linked objects here have special shapes.These special shapes give the effect that the extended portions of thetwo linked objects can rotate relatively to each other, and that theirrotation is confined within two (imaginary) parallel planes separated bya distance equal to the identical heights of their elongated portions.Externally, hollow object 5633 has an opening at one end (5633 h) of itselongated portion, and at the other end it has two concentriccylindrical portions 5633 a and 5633 b with a common opening; andinternally there is a tunnel that starts at 5633 h, runs through theentire elongated portion, enters 5633 a, and exits at the common openingof 5633 a and 5633 b. Hollow object 5634 has an opening at one end (5634h) of its elongated portion, and at the other end it has two portions5634 a and 5634 b with a common opening; and internally there is atunnel that starts at 5634 h, runs through the entire elongated portion,enters 5634 a, and exits at the common opening of 5634 a and 5634 b.Portion 5634 a holds the disks, the spring washer, and the screw. Theexternal size and circular shape of 5633 b match those internal ones of5634 b so that they can be nested as concentric cylinders; and thisrotatably links 5633 and 5634 together. Dashed line 5670 shows how awiring cable can run from the inside of the elongated portion of 5633,through the inside of 5633 a and 5633 b, into the inside of 5634 a, andfurther into the inside of the elongate portion of 5634, without leavingthe enclosure of the joint. Notice here how the cable (5670) goes aroundshaft 5680 inside 5633 a and 5633 b.

FIG. 55 shows an embodiment of a friction joint (5700) of the presentinvention. FIG. 55A is an exploded view; FIG. 55B is a perspective view;and FIG. 55C is a sectional view. The two linked objects are 5733 and5734. The basic idea here is the same as that of friction joint 5000B(FIG. 49). A noticeable difference is that the “hollow shaft” here isserved by a deformed small diameter portion (5733 a) of 5733. We usedifferent labels here for the discs (5750 and 5760), the spring washing(5710), the screw (5720), and the cap (5790); but they serve basicallythe same functions as their counterparts in joint 5000B (FIG. 49).Because the “shaft” is hollow, there is no need to have a pass way forthe wiring cable to bypass the friction mechanism; the cable can simplyruns inside the “shaft” and therefore the friction mechanism.

FIG. 56 shows an embodiment of a friction joint (5800) of the presentinvention.

FIG. 56A is an exploded view. The two linked hollow objects are 5837 and5838, each having a tunnel to allow the wiring cable to run through. Twoshafts 5887 and 5888 are firmly mounted on the 5837 and 5838,respectively. Shafts 5887 and 5888 respectively have deformed smalldiameter portions 5887 c and 5888 c, each having screw thread at theend. There are three groups of discs: upper row of 5850 engaged with5887, and lower row of 5850 engaged with 5888, and 5860 engaged withboth 5887 and 5888. The discs from different groups are interposed andplaced closely for frictional contact. A pair of spring washers (5810)and a pair of screws (5820) are respectively engaged with 5887 c and5888 c to tighten the frictional contact between the discs. Component5872 is optional; and when included, it is used to enhance thestructural stability of the mechanism and also to prevent the edges of5837 a and 5838 a from “cutting” the cable during rotation.

FIG. 56B is a perspective view of 5837. The corresponding perspectiveview of 5838 would be similar.

FIG. 56C shows perspective split views of 5887 and 5888. Shafts 5887 and5888 respectively have deformed small diameter portions 5887 c and 5888c for engaging with the discs. Both 5887 c and 5888 c have screw threadsat the ends.

FIG. 56D shows the cross section views of the deformed small diameterportions of the shafts 5887 c and 5888 c, and the discs in group 5850and 5860. A disc in group 5850 has a circular edge and a deformedinsertion hole that matches the deformed shapes of small diameterportion 5887 c and 5888 c. A disc in group 5860 has two circularinsertion holes. Because the matching of the shapes (and sizes), when5837 and 5838 respectively rotate around shafts 5887 and 5888, the upperrow of discs in group 5850 rotates in sync with 5837, the lower row ofdiscs in group 5850 rotates in sync with 5838, while discs in group 5060do not rotate with either of the shafts. The rotational friction betweenthe two rows of discs in group 5850 against the discs in group 5860contributes the friction of the joint mechanism.

FIG. 56E is a perspective view of joint 5800 when the 5837 and 5838 arelinked together.

FIG. 56F is a sectional view of the joint mechanism. The dashed line(5870) shows how a wiring cable can run from the inside of 5837 to theinside of 5838.

FIG. 56G and FIG. 56H illustrate that cover 5840 is optional. Themechanism can function even without 5840.

FIG. 56I shows that shafts can be mounted differently on the two hollowobjects (relabeled as 5834 and 5835 from 5837 and 5838, respectively),in a way similar to how shaft 5080 is mounted on 5033 in joint mechanism5000 as shown in FIG. 47.

FIG. 57 shows an embodiment of a friction joint (5900) of the presentinvention. FIG. 57A is an exploded view; FIG. 57B is a perspective view;and FIG. 57C is a perspective view; and FIG. 57D is a sectional view.The two linked objects are 5937 and 5738. The basic idea here is thesame as that of friction joint 5800 (FIG. 56). A noticeable differenceis that the “hollow shafts” here are served by deformed small diameterportions of 5937 a and 5938 a. We use different labels here for thediscs (5950 and 5960), the spring washing (5910), the screw (5920), andthe cover (5940) along with its cap (5941); but they serve basically thesame functions as their counterparts in joint 5800 (FIG. 56). Dashedline 5970 shows how a wiring cable can run from inside of 5937 to insideof 5938. Component 5972 is optional; and when included, it is used toenhance the structural stability of the mechanism and also to preventthe edges of 5937 a and 5938 a from “cutting” the cable during rotation.

FIG. 58 shows some of the possible ways how friction joint mechanism5000 can be used in connecting two arm sections of the variousextensions.

FIG. 59 shows some of the possible ways in which how friction jointmechanism 5000 as well as 5100 can be used to create combo joints.

Support for Joint Notations in FIG. 2

Up to this point, we have presented mechanical joints to support therotatable joint notation in FIG. 2. The following is a summary.

-   -   Notation in FIG. 2A can be implemented by joint 5500 (FIG. 53),        or the mechanism in FIG. 58D.    -   Notation in FIG. 2B can be implemented by joints 5600 (FIG. 54).    -   Notation in FIG. 2C can be implemented by joints 5800 (FIG. 56),        5900 (FIG. 57), and the mechanism in FIG. 58F.    -   Notation in FIG. 2D can be implemented by joints 5000 (FIG. 47),        5000A (FIG. 48), 5000B (FIG. 49), and 5700 (FIG. 55).    -   Notation in FIG. 2F can be implemented by combo-joints shown in        FIG. 59A and FIG. 59B.    -   Notation in FIG. 2G can be implemented by joints 5100 (FIG. 50)        and 5300 (FIG. 51).

A Method for Installing Wiring Cables in Multi-sectioned Arms

FIG. 60 presents a method for assembling multi-sectioned arms withembedded wiring cable when the cable used is pre-connected withconnectors at the ends.

FIG. 60A shows a wiring cable (5275) that is pre-connected withconnectors 5275 a, 5275 b, and 5275 c at its ends. This is typical ofthe wiring cables between the displays and the bases for many of thetoday's notebook computers based on the conventional clamshell design.The figure also shows some solid pieces, 5294 a and 5294 b, 5295 a and9295 b, and 5296 a and 5296 b, for constructing hollow objects that thewiring cable needs to run through. At least two of the connectors (5275a and 5275 b) on the opposite ends of the wiring cable (parallel cable)are too large to pass through the narrow tunnels of the objects afterthe separate solid pieces are merged into the desirable objects. Themethod here is to place the wiring cable before merging the separatesolid pieces. Different from other hollow objects in the figure, 5293 isnot constructed from separate solid pieces. As amplified in FIG. 60F,object 5293 has a narrow gap 5293 a along its tunnel. To run the entirecable through the tunnel of 5293, the method here is to slide throughthe gap at 5293 a, one by one, wires of the cable. The width of theslide-through gap (i.e. 5293 a) needs to be just slightly wider than thediameter of each individual wire. (Note: For the parallel cable betweenthe base and the display of today's typical notebook computer, each suchwire is ultra-thin, usually about 0.5 mm in diameter or thinner.)

FIG. 60B is a perspective view of wiring cable 5275 running through thehollows objects that are merged together from the separate solid piecesas shown in FIG. 60A.

FIG. 60C shows how two solid pieces, 5294 a and 5924 b, can embrace toform a tunnel.

FIG. 60D shows how 5295 a and 5295 b can form a circular tunnel bymerging along their edges. FIG. 60E shows that 5296 a can slide into5296 b to close the opening of 5296 a.

In actually implementation, one possible combination would be to useseparate pieces to form components that are exposed, and to useslide-through gaps for parts that are hidden after assembly.

The examples here are provided for illustrative purposes. There are manyother ways to form a hollow object from two or more separate pieces. Inmerging separate solid pieces to form a hollow object, the formation canbe secured using standard mechanisms such as screw, superglue, lockinggroove etc. After the cable is placed inside a hollow object, theslide-through gap, such as 5293 a, should be filled, with a narrowstrip, rubber glue etc. Such details are easy to people skilled in theart, and therefore not elaborated here.

Attachment of Multi-sectioned Arms to the Base and the Display

FIG. 61 shows some possible ways for mounting a multi-sectioned arm tothe base and the display of a portable computer of the presentinvention. A tunnel can be provided directly on the base (as shown inFIG. 61C) or the display so that an end section of the multi-section canbe inserted. Alternative, an arm attachment mechanism can be mounted tothe display and the base, as shown in FIG. 61A and FIG. 61B.

FIG. 61A shows that, using part 5246 c, the arm attachment mechanism(5246) can be hung off the bottom of the display. The opening (5246 a)on top of 5246 is for the wiring cable to pass between the arm and thebase. Next to opening 5246 a is a “slide-through gap” for the individualwires of the wiring cable to slide into 5246 a (as discussed earlier inFIG. 60.)

FIG. 61B shows that arm attachment mechanism (5247) can be mounted onthe back edge of the base of the portable computer. Notice that, inactual implementations, such an arm attachment mechanism can also bemounted on other sides and edges of the base and the display.

FIG. 61C. shows that an insertion tunnel can be created on the base (andsimilarly on the display) of the portable computer of the presentinvention. Depending on whether or not it is desirable for the insertedportion of the arm section to rotate relatively to the tunnel, we canchoose the shape of the tunnel to be of either cylindrical shape toallow relative rotation or a special shape matching that of the insertedportion to prevent relative rotation. In FIG. 61C, a cubical tunnel ischosen.

We should point out that the methods discussed here for mounting anattachment mechanism to the base and the display are also applied todirectly mount the end sections or the built-in connection pivots of amulti-sectioned arm, as shown in FIG. 62.

Putting It All Together: A Complete Design of Multi-Sectioned Arms for aPortable Computer

FIG. 62 presents a portable computer (5200) with two double-sectionedarms according to the present invention. Computer 5200 resemblesportable computer 200 in FIG. 18A, allowing the same set of possiblemovements and configurations. This is to show how the mechanismspresented earlier can be used to implement the multi-sectioned arms of aportable computer of the present invention. Designs of the mechanicalparts and the structures of the arms are presented in great details,including the joints, the hollow arm sections, wiring, and theconnection pivots for mounting the arms on the display and the base ofthe computer.

FIG. 62A is a perspective front view of computer 5200. The computer isin an open position with the arms fully stretched in the verticaldirection, screen 98 facing the user, and keyboard 87 facing upward. Thetwo arms are similar, and therefore we only present the details of theleft arm. There are four pivotal axes. Pivotal axis 5221 around 5241supports the relative rotation of display 90 and the upper sections ofthe arms (5237 and its counterpart on the right arm). Pivotal axis 5224around 5242 supports the relative rotation of the lower sections of thearms (5238 and its counterpart on the right arm) and base 80. Pivotalaxes 5222 and 5223 at joint 5240 support the relative folding andstretching of the upper and lower arm sections.

FIG. 62B is a partially exploded view of the left arm of computer 5200.Details of the lower connection pivot (5242) are not shown, itsstructure similar to that of the upper connection pivot, with thepossible exception of having different number of discs due to differentfriction needs.

The middle joint (with cover 5240) is based on friction joint mechanism5800 in FIG. 56, although the parts are given different labels here fromthose in FIG. 56. Specifically, 5250 represents two rows of discs forengaging with shafts 5282 and 5283, respectively; 5260 is the group ofthe discs for engaging with both shafts simultaneously; and 5220 and5210 are a pair of spring washer and screw for tightening the frictionalcontact of the discs in group 5250 and 5260. Part 5272 providesadditional stability of the structure and protects the wiring from theedges of 5237 d and 5238 d during arm rotation. Compared to FIG. 56, onespecial feature here is the slide-through gaps (5272 a and 5272 b) onpart 5272. Such gaps are used for installation of a wiring cable that ispre-connected with connectors on its ends (as discussed earlier indetails in FIG. 60.).

The upper connection pivot (with cover 5241) is based on mechanism 5400in FIG. 52, although its components are given different labels here fromthose in FIG. 52. Specifically, 5251 is the group of discs for engagingwith shaft 5281; 5261 is the group of discs for engaging the inside of5241; and spring washer 5211 and screw 5221 are used to tighten thefrictional contact between friction discs in groups 5251 and 5261.

FIG. 62C shows the external structure of the connection pivot (5241).The structure and function of this part is similar to 5441 in jointmechanism 5400 in FIG. 52. The difference here is the slide-through gap(5241 a) useful for wiring cable installation (as discussed earlier indetails in FIG. 60).

FIG. 62D shows two perspective views of hollow part 5237 c. Part 5237 d(not shown in this figure) is similar in structure. There is aslide-through gap and a wider opening along the gap on part 5237 c. Theslide-through gap is for cable installation. The wider opening is usedafter installation to receive the wiring cable from the tunnel in theelongated portion of section 5237.

FIG. 62E shows the structure of shaft 5281. It has a large diameter topportion 5281 a, a cubical portion 5281 b (matching the shape ofinsertion hole 5237 h on the top portion of 5237 a), a mid portion 5281c (of cylindrical shape so as to minimize the wearing with the wiringcable during rotation), and deformed small diameter portion 5281 d withscrew thread at the end.

FIG. 62F is an exploded view of arm section 5237. It shows how hollowarm section 5237 is composed of separate solid parts. Specifically, theelongated portion of the 5237 b is embraced by 5237 a to form theelongated portion of 5237. (This idea is similar to the one shown inFIG. 60C.) Shaft 5281 inserts into insertion hole 5237 h. The mountingportion (5281 b) of the shaft matches 5237 h in size and shape, so thatshaft 5281 does not rotate relative to 5237 after installation. Part5237 c is inserted in the top hollow portion of 5237 a so that shaft5281 also inserts into 5237 c. Part 5237 c is hollow and has an openingand a slide-through gap on the side. The opening is for the wiring cableto come through from 5237 c after installation; and the slide-throughgap is needed for wiring cable installation (as discussed earlier indetails in FIG. 60.) The installations of part 5237 d and shaft 5282 aresimilar to those of 5237 c and shaft 5281, respectively.

FIG. 62G shows three perspective views of 5237 a, from an angle (betweenthe front and a side), from the front, and from the back.

FIG. 62H shows three perspective views of 5237 b, side view, front view,and back view. On the top portion of 5237 b, there is an insertion hole(5237 i).

It should be mentioned that the drawings are for illustrative purposesonly; and in actual implementation, the relative sizes of the componentsdo not have to be proportional to those in the drawings.

The foregoing descriptions of specific embodiments of the presentinvention have been presented for purposes of illustration anddescription. They are not intended to be exhaustive or to limit theinvention to the precise forms disclosed, and obviously manymodifications and variations are possible in light of the aboveteaching. The embodiments were chosen and described in order to bestexplain the principles of the invention and its practical application,to thereby enable others skilled in the art to best utilize theinvention and various embodiments with various modifications as aresuited to the particular use contemplated. It is intended that the scopeof the invention be defined by the Claims appended hereto and theirequivalents. Therefore, the scope of the invention is to be limited onlyby the following claims.

1. A pivotal friction joint, comprising, (a) a first hollow member and asecond hollow member; (b) a shaft, firmly attached to said first member;(c) a first group of one or more discs, unrotatably mounted on saidshaft, said first group of discs being housed inside and rotatablerelative to said second hollow member; (d) a second group of one or morediscs, housed inside and unrotatable relative to said second hollowmember, the discs of said second group being rotatably mounted on saidshaft and interposed between the discs of said first group; (e) anelastic means, mounted on said shaft for urging the discs of said firstand second groups into contact with each other; (f) a fastening means,attached to an end of said shaft; wherein disposed between saidfastening means and said two groups of discs, said elastic means isplaced under a desired load.
 2. The friction joint of claim 1, wherein acable is allowed to run from the inside of said first member into theinside of said second member, without leaving the enclosure of saidpivotal joint.
 3. The friction joint of claim 2, wherein said cablebypasses said two groups of discs.
 4. The friction joint of claim 1,wherein said shaft is a hollow portion of said first member; and a cableis allowed to run from the inside of said shaft, directly into theinside of said second member, while indirectly passing through said twogroups of discs.
 5. The friction joint of claim 1, wherein each disc ofsaid first group has a deformed insertion-hole; each disc of said secondgroup has a circular insertion-hole; said shaft has a deformed smalldiameter portion that inserts into said insertion-holes of said twogroups of discs; said elastic means comprises one or more spring washersor disc springs; and said fastening means is a screw or screw nut.
 6. Apivotal friction joint, comprising, (a) a first hollow member and asecond hollow member; (b) a first shaft, firmly attached to said firstmember; (c) a second shaft, firmly attached to said second member; (d) afirst group of one or more discs, unrotatably mounted on said firstshaft; (e) a second group of one or more discs, unrotatably mounted onsaid second shaft; (f) a third group of one or more discs, rotatablymounted on said first shaft and also rotatably mounted on said secondshaft, the discs of said third group being interposed between the discsof said first group and also interposed between the discs of said secondgroup; (g) a first elastic means, mounted on said first shaft for urgingthe discs of said first and third groups into contact with each other;(h) a second elastic means, mounted on said second shaft for urging thediscs of said second and third groups into contact with each other; (i)a first fastening means, attached to an end of said first shaft; (j) asecond fastening means, attached to an end of said second shaft; whereindisposed between said first fastening means and the discs of said firstand third groups, said first elastic means is placed under a desiredload; and wherein disposed between said second fastening means and thediscs of said second and third groups, said second elastic means isplaced under a desired load.
 7. The pivotal friction joint of claim 6,further comprising a cover for housing said three groups of discs, saidtwo elastics means, said two fastening means, and said two shafts; andwherein a cable is allowed to run from the inside of said first member,through said cover, and into the inside of said second member.
 8. Thefriction joint of claim 7, wherein said cable bypasses said three groupsof discs.
 9. The friction joint of claim 7, wherein said first shaft isa hollow portion of said first member; said second shaft is a hollowportion of said second member; and a cable is allowed to run from theinside of said first shaft, through said cover, and into the inside ofsaid second member, while indirectly passing through the discs of saidthree groups.
 10. The friction joint of claim 6, wherein each disc ofsaid first and second groups has a deformed insertion-hole; each disc ofsaid third group has a circular insertion-hole; said first shaft has adeformed small diameter portion that inserts into said insertion-holesof said first and third groups of discs; said second shaft has adeformed small diameter portion that inserts into said insertion-holesof said second and third groups of discs; each of said two elastic meanscomprises one or more spring washers or disc springs; and each of saidfastening means is a screw or screw nut.
 11. A method for assembling amulti-sectioned arm with embedded wiring cable for connecting thedisplay and the base of a portable electronic device, comprising, (a)providing components of said arm for assembly; wherein for each hollowcomponent that said cable needs to pass through, either said hollowcomponent is provided with a slide-through gap for said cable to slideinto, or said hollow component is provided in two or more separate solidpieces to be merged together; (b) providing a wiring cable having two ofmore ends pre-connected with connectors; (c) sliding said cable intoeach said hollow component that is provided with a slide-through gap;and for each said hollow component that is provided in separate solidpieces, placing said cable through, then completing the merging of saidseparate solid pieces; and (d) assembling said arm completely after saidcable is placed inside said hollow components.
 12. The method as recitedin claim 11, wherein said cable is a parallel cable consisting ofindividual wires; wherein each said slide-through gap is wide enough forevery said wire to slide through, but not wide enough for the entirecable to slide through.